CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the benefit of
U.S. Provisional Patent Application Serial No. 61/340,980, filed on March 25, 2010, and entitled "System, Apparatus and Method for Imaging," and
U.S. Provisional Patent Application Serial No. 61/422,313, filed on December 13, 2010, and entitled "System, Apparatus and Method for Imaging."
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH
BACKGROUND OF THE INVENTION
[0003] The field of the invention is systems and methods for medical imaging. More particularly,
the invention relates to systems and methods for improving tractography and tractographic
processes, for example, by producing and using a subject-specific coordinate system
that conforms to a tissue of interest or considering the interrelation of tracts during
tractography or processes related to tractography.
[0004] Understanding brain connectivity on a global scale is likely a prerequisite to understanding
brain function. Whereas studies in animals with tract-tracers have identified individual
pathways and their topology as complex networks, studies of the geometric organization
of connectivity in the context of brain evolution, development, plasticity, neural
coding, and large-scale cerebral specialization have suggested much simpler organization.
The need to synthesize these disparate viewpoints is long recognized and has prompted
technical innovation and basic discovery. That is, the research and development to
date has been able to capture small and explain small portions of the overall brain
architecture, but there has been a clear desire to determine a single view to brain.
However, while progress has been achieved outside the forebrain, no single picture
yet describes both the geometric and topologic character of cerebral connectivity.
Particularly, it has been significantly difficult to accurately map cerebral pathways
in an anatomical context, or anatomical relations between pathways in a single brain.
[0005] The large-scale structure of the primate cerebral connectome - the totality of fiber
pathways of the cerebral white matter - has been elusive. In the late 19th to early
20th century investigations of connectional neuroanatomy using traditional dissection
and microscopy uncovered basic principles of large-scale brain organization and development.
By the mid 20th century, these methods were supplanted by more precise and reproducible
methods of fiber tracing. The success of the fiber tracing approach, and its emphasis
on point-to-point connectivity, however, tended to remove from view questions about
the organization of the brain at larger scales. The three-dimensional relations between
fiber pathways are difficult to discover with fiber tracing techniques, and the presumption
is often made that these relations are of secondary importance.
[0006] Recently, magnetic resonance imaging ("MRI") methods, such as diffusion MRI, have
been developed to map major fiber pathways in a single brain. Diffusion MRI now affords
a means by which to map the connectional anatomy of a single brain in its entirety,
and to do so rapidly, three-dimensionally, nondestructively, and noninvasively. In
the development of this technology, a key advance was the recognition of the problem
of ubiquitous fiber crossings in the brain. The difficulty fiber crossings posed for
early diffusion tensor imaging ("DTI") mapping of fiber pathways helped lead to the
development of methods for accurately resolving fiber crossings, such as diffusion
spectrum imaging ("DSI"), Q-Ball imaging, q-space imaging ("QSI"), and other related
techniques. While these methods provide an ability to resolve complex fiber architecture
at each location, the quantitation of complex fiber architecture and of diffusion
beyond the tensor remains challenging, and an active area of research. Document
WO 2009/088965 A1 relates to a magnetic resonance imaging (MRI) system, comprising: a MRI scanner;
a signal processing system in communication with the magnetic resonance imaging scanner
to receive magnetic resonance (MR) signals for forming magnetic resonance images of
a subject under observations; a data storage unit in communication with the signal
processing system, wherein the data storage unit contains database data corresponding
to a soft tissue region of the subject under observation. The database data includes
information identifying at least one soft tissue substructure encompassed by the soft
tissue region of the subject under observation. The signal processing system is adapted
to process MR signals received from the MRI scanner to automatically identify at least
one soft tissue substructure encompassed by the soft tissue region of the subject
under observation.
SUMMARY OF THE INVENTION
[0007] The invention is defined by the appended independent claims with preferred configurations
being specified in dependent claims.
[0008] The foregoing and other aspects and advantages of the invention will appear from
the following description. In the description, reference is made to the accompanying
drawings which form a part hereof, and in which there is shown by way of illustration
a preferred embodiment of the invention. Such embodiment does not necessarily represent
the full scope of the invention, however, and reference is made therefore to the claims
for interpreting the scope of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009]
FIG. 1 is a block diagram of an exemplary magnetic resonance imaging ("MRI") system
that employs the present invention.
FIG. 2 is a graphic illustration of an exemplary diffusion weighted imaging ("DWI")
spin-echo, echo planar imaging ("EPI") pulse sequence for directing the MRI system
of FIG. 1 to acquire diffusion data.
FIG. 3 is a pictorial representation of an exemplary superior longitudinal fasciculus
I fiber path and corpus callosum fiber path that cross in a volume-of-interest and
a grid structure coordinate system mapped therebetween in accordance with embodiments
of the present invention.
FIG. 4 is a graphic representation of a plurality of vectors determined using a tractography-type
process and processed in accordance with the present invention.
FIG. 5 is a graphic representation of a sheet of fiber tracts and orthogonal vectors
determined in accordance with the present invention.
FIG. 6 is a flowchart setting forth the steps of an exemplary method for producing
a coordinate system that is conformal to a substantially orthogonal three-dimensional
grid structure and to diffusion information obtained with an MRI system.
FIG. 7A is pictorial representation of an exemplary fiber bundle and a three dimensional
grid structure coordinate system mapped therebetween in accordance with the present
invention.
FIG. 7B is pictorial representation of an exemplary brain anatomy and a three dimensional
grid structure coordinate system mapped therebetween in accordance with the present
invention.
FIG. 8 is a flowchart setting forth the steps of an exemplary method for producing,
or defining, a grid structure coordinate system using diffusion information contained
in a vector field that describes tissue pathways, such as white matter tissue fiber
paths.
FIG. 9 is a flowchart setting forth the steps of an exemplary method for producing,
or defining, a grid structure coordinate system using topological properties of tissue
pathways, such as white matter tissue fiber paths.
FIG. 10 is a flowchart setting forth the steps of an exemplary method for producing
fiber sheet conformal coordinates.
FIG. 11A is a flowchart setting forth the steps of an exemplary method for comparing
medical images of two or more subjects using a grid structure coordinate system.
FIG. 11B is a flowchart setting forth the steps of an exemplary method for producing
an average image from medical images obtained for multiple different subjects, and
using a grid structure coordinate system.
FIG. 11C is a flowchart setting forth the steps of an exemplary method for measuring
and producing an image representative of the connectivity of fiber pathways in a subject's
brain using a grid structure coordinate system.
FIG. 11D is a flowchart setting forth the steps of an exemplary method for calculating
a fiber density measure using a grid structure coordinate system.
FIG. 11E is a flowchart setting forth the steps of an exemplary method for measuring
the accuracy of a grid structure coordinate system.
FIG. 11F is a flowchart setting forth the steps of an exemplary method for producing
an image of a subject's anatomy, such as the subject's brain, at a different age of
the subject using a grid structure coordinate system.
DETAILED DESCRIPTION OF THE INVENTION
[0010] In general, the present invention relates to systems and methods for producing and
using a conformal coordinate system of a tissue of interest in a subject from diffusion
information related to the tissue of interest that is acquired with magnetic resonance
imaging ("MRI"). A subject may include an animal subject including humans and other
mammals, and an exemplary tissue of interest may be brain tissue, including white
matter tissue. The coordinate system is generally structured such that tissue pathways,
such as white matter fiber pathways, are organized into a two-dimensional or three-dimensional
grid. These grids are substantially orthogonal in as much as the pathways contained
within the grid and arranged with respect to the coordinate system intersect at substantially
right angles. The present invention recognizes that this coordinate system and the
underlying "grid structure" may be standardized across different subjects. A coordinate
system that is representative of such "grid structures" is herein referred to as a
"grid structure coordinate system." Exemplary grid structure coordinate systems, systems
and methods for defining such coordinate systems, and systems and methods for using
such coordinate systems are described below in detail. First, a brief description
of an exemplary MRI system and data acquisition scheme for use with the present invention
are provided.
MRI System
[0011] Referring particularly now to FIG. 1, an exemplary MRI system 100 for use with the
present invention is illustrated. The MRI system 100 includes a workstation 102 having
a display 104 and a keyboard 106. The workstation 102 includes a processor 108, such
as a commercially available programmable machine running a commercially available
operating system. The workstation 102 provides the operator interface that enables
scan prescriptions to be entered into the MRI system 100. The workstation 102 is coupled
to four servers: a pulse sequence server 110; a data acquisition server 112; a data
processing server 114, and a data store server 116. The workstation 102 and each server
110, 112, 114 and 116 are connected to communicate with each other.
[0012] The pulse sequence server 110 functions in response to instructions downloaded from
the workstation 102 to operate a gradient system 118 and a radiofrequency ("RF") system
120. Gradient waveforms necessary to perform the prescribed scan are produced and
applied to the gradient system 118, which excites gradient coils in an assembly 122
to produce the magnetic field gradients
Gx, Gy, and
Gz used for position encoding MR signals. The gradient coil assembly 122 forms part
of a magnet assembly 124 that includes a polarizing magnet 126 and a whole-body RF
coil 128.
[0013] RF excitation waveforms are applied to the RF coil 128, or a separate local coil
(not shown in FIG. 1), by the RF system 120 to perform the prescribed magnetic resonance
pulse sequence. Responsive MR signals detected by the RF coil 128, or a separate local
coil (not shown in FIG. 1), are received by the RF system 120, amplified, demodulated,
filtered, and digitized under direction of commands produced by the pulse sequence
server 110. The RF system 120 includes an RF transmitter for producing a wide variety
of RF pulses used in MR pulse sequences. The RF transmitter is responsive to the scan
prescription and direction from the pulse sequence server 110 to produce RF pulses
of the desired frequency, phase, and pulse amplitude waveform. The generated RF pulses
may be applied to the whole body RF coil 128 or to one or more local coils or coil
arrays (not shown in FIG. 1).
[0014] The RF system 120 also includes one or more RF receiver channels. Each RF receiver
channel includes an RF amplifier that amplifies the MR signal received by the coil
128 to which it is connected, and a detector that detects and digitizes the
I and Q quadrature components of the received MR signal. The magnitude of the received
MR signal may thus be determined at any sampled point by the square root of the sum
of the squares of the
I and Q components:

and the phase of the received MR signal may also be determined:

[0015] The pulse sequence server 110 also optionally receives patient data from a physiological
acquisition controller 130. The controller 130 receives signals from a number of different
sensors connected to the patient, such as electrocardiograph ("ECG") signals from
electrodes, or respiratory signals from a bellows or other respiratory monitoring
device. Such signals are typically used by the pulse sequence server 110 to synchronize,
or "gate," the performance of the scan with the subject's heart beat or respiration.
[0016] The pulse sequence server 110 also connects to a scan room interface circuit 132
that receives signals from various sensors associated with the condition of the patient
and the magnet system. It is also through the scan room interface circuit 132 that
a patient positioning system 134 receives commands to move the patient to desired
positions during the scan.
[0017] The digitized MR signal samples produced by the RF system 120 are received by the
data acquisition server 112. The data acquisition server 112 operates in response
to instructions downloaded from the workstation 102 to receive the real-time MR data
and provide buffer storage, such that no data is lost by data overrun. In some scans,
the data acquisition server 112 does little more than pass the acquired MR data to
the data processor server 114. However, in scans that require information derived
from acquired MR data to control the further performance of the scan, the data acquisition
server 112 is programmed to produce such information and convey it to the pulse sequence
server 110. For example, during prescans, MR data is acquired and used to calibrate
the pulse sequence performed by the pulse sequence server 110. Also, navigator signals
may be acquired during a scan and used to adjust the operating parameters of the RF
system 120 or the gradient system 118, or to control the view order in which k-space
is sampled. The data acquisition server 112 may also be employed to process MR signals
used to detect the arrival of contrast agent in a magnetic resonance angiography ("MRA")
scan. In all these examples, the data acquisition server 112 acquires MR data and
processes it in real-time to produce information that is used to control the scan.
[0018] The data processing server 114 receives MR data from the data acquisition server
112 and processes it in accordance with instructions downloaded from the workstation
102. Such processing may include, for example: Fourier transformation of raw k-space
MR data to produce two or three-dimensional images; the application of filters to
a reconstructed image; the performance of a backprojection image reconstruction of
acquired MR data; the generation of functional MR images; and the calculation of motion
or flow images.
[0019] Images reconstructed by the data processing server 114 are conveyed back to the workstation
102 where they are stored. Real-time images are stored in a data base memory cache
(not shown in FIG. 1), from which they may be output to operator display 112 or a
display 136 that is located near the magnet assembly 124 for use by attending physicians.
Batch mode images or selected real time images are stored in a host database on disc
storage 138. When such images have been reconstructed and transferred to storage,
the data processing server 114 notifies the data store server 116 on the workstation
102. The workstation 102 may be used by an operator to archive the images, produce
films, or send the images via a network to other facilities.
Data Acquisition - Example Pulse Sequence
[0020] To acquire image data that can be used to produce or define a coordinate system in
accordance with embodiments of the invention, diffusion imaging schemes such as diffusion
spectrum imaging ("DSI"), Q-Ball imaging, q-space imaging ("QSI"), and diffusion tensor
imaging ("DTI") may be used. It will be appreciated by those skilled in the art that
for these imaging schemes several different pulse sequences may be implemented to
acquire image data. One such exemplary pulse sequence is described below.
[0021] By way of example, a spin-echo, echo planar imaging ("EPI") pulse sequence for acquiring
image data with an MRI system is illustrated in FIG. 2. While this exemplary pulse
sequence is illustrated here, it will be appreciated by those skilled in the art that
other pulse sequences can be employed to perform diffusion data acquisition, such
as gradient-echo based sequences and other spin-echo based sequences, including, for
example, twice refocused spin echo ("TRSE") EPI sequences. Additionally, pulse sequences
that employ hybrid two dimensional echo-planar and 3DFT spatial encoding may be used.
[0022] The spin-echo EPI sequence begins with an RF excitation pulse 202 that is played
out in the presence of a slice selective gradient 204. To mitigate signal losses resulting
from phase dispersions produced by the slice selective gradient 204, a rephasing lobe
206 is applied after the slice selective gradient 204. Next, a rephasing RF pulse
208 is applied in the presence of another slice selective gradient 210. In order to
substantially reduce unwanted phase dispersions, a first crusher gradient 212 bridges
the slice selective gradient 210 with a second crusher gradient 214. The slice-selective
gradient 210 and crusher gradients 212 and 214 are further bridged by a first and
second diffusion weighting gradient, 216 and 218, respectively. These diffusion weighting
gradients 216 and 218 are equal in size, that is, their areas are equal. The diffusion
weighting gradients 216 and 218, while shown on a separate "diffusion weighting" gradient
axis, are in fact produced through the application of diffusion weighting gradient
lobes along each of the slice-encoding, phase-encoding, and frequency-encoding gradient
directions. By changing the amplitudes and other characteristics of the diffusion
weighting gradient lobes, the acquired echo signals can be weighted for diffusion
occurring along any arbitrary direction. For example, when the diffusion weighting
gradients 216 and 218 are composed solely of gradient lobes applied along the
Gz gradient axis, then the acquired echo signals will be weighted for diffusion occurring
along the z-direction. For another example, however, if the diffusion weighting gradients
216 and 218 are composed of gradient lobes applied along both the
Gx and
Gy gradient axes, then the echo signals will be weighted for diffusion occurring in
the x-y plane along a direction defined by the relative amplitudes of the gradient
lobes.
[0023] Diffusion weighting of the acquired echo signals is provided when spins undergo random
Brownian motion, or diffusion, during the time interval, Δ, spanned between the application
of the first and second diffusion gradients216 and 218, respectively. The first diffusion
weighted gradient 216 dephases the spins in the imaging volume, whereas the second
diffusion weighted gradient 218 acts to rephase the spins by an equal amount. When
spins undergo random diffusive motion during this time interval, however, their phases
are not properly rephased by the second diffusion gradient 218. This phase difference
results in a signal attenuation related to the diffusion occurring along the direction
prescribed by the diffusion weighting gradients 216 and 218. The more diffusion that
occurs, the more signal attenuation that results.
[0024] Image data is acquired by sampling a series of diffusion weighted spin echo signals
in the presence of an alternating readout gradient 220. The alternating readout gradient
is preceded by the application of a pre-winding gradient 222 that acts to move the
first sampling point along the frequency-encoding, or readout, direction by a distance
Δ
kx in k-space. Spatial encoding of the echo signals along a phase-encoding direction
is performed by a series of phase encoding gradient "blips" 224, which are each played
out in between the successive signals readouts such that each echo signal is separately
phase encoded. The phase encoding gradient blips 224 are preceded by the application
of a pre-winding gradient 226 that acts to move the first sampling point along the
phase-encoding direction a distance Δ
ky in k-space. Together, the pre-winding gradients 222 and 226 serve to begin the sampling
of k-space at a defined k-space location (
kx,ky)
.
[0025] In an exemplary implementation, a DSI imaging scheme with the following parameters
may be used: a cubic lattice of 515 diffusion gradient values, peak diffusion sensitivity
[b-value ) of 4 × 10
4 seconds per millimeter-squared (
s/
mm2), diffusion gradient times of Δ = 22 milliseconds and
δ = 16 milliseconds, and peak gradient intensity of 380 milli-Tesla per meter. Image
matrices may be 80 × 80 × 80 to 140 x 140 × 140 with isotopic three-dimensional resolution
of 300-500 micrometers.
General Description
[0026] When used to examine the brain, the grid structure coordinate system is useful to
describe, simplify, and compare other images of the brain, and can be implemented
to reliably compare one brain to another. The produced coordinate system may also
be useful for creating representations and measures of brain connectivity that are,
when compared to traditional representations and measures, easy to understand, easy
to measure, and easy to compare between individuals. While the description provided
herein makes reference to examples of determining a coordinate system that conforms
to the brain and white matter tissue contained therein, it will be appreciated by
those skilled in the art that the coordinate system may also be produced for other
tissues, for example, such as skeletal muscle, smooth muscle, and cardiac muscle.
[0027] The present invention recognizes that the typical structure of cerebral white matter,
when properly construed, is that of a biaxial or tri-axial grid of mutually orthogonal,
and potentially interwoven, fiber paths. Thus, the present invention recognizes that
white matter tissue can be understood to conform to a substantially orthogonal grid
structure. To uncover this conformity, however, a grid structure coordinate system
may be defined so that the white matter fibers paths may be mapped into that coordinate
system. Such a grid structure coordinate system may be defined, for example, to include
three principal axes: a longitudinal axis, a transverse axis, and a dorsoventral axis.
While the grid structure coordinate system may be defined over these three principal
axes, in some portions of the brain the grid structure coordinate system may be a
two-dimensional coordinate system that is defined by only two of the aforementioned
principal axes.
[0028] Generally, a grid structure coordinate system can be defined over a portion of a
subject's brain, such as the cerebrum, the cerebellum, the pons, the medulla, or portions
thereof, such as the telencephalon, the diencephalon, and the mesencephalon, or portions
thereof, such as an anatomical region-of-interest in the telencephalon, and so on.
By defining grid structure coordinate systems over these smaller portions of the brain,
ensembles of grid structure coordinate systems over a single brain can be defined.
These ensembles may be connected together or may be analyzed, for example, by measuring
their mutual coherence. Furthermore, the number of grid structure coordinate systems
contained in an ensemble may be allowed to grow infinitely large, thereby resulting
in a set of probabilistic coordinates.
[0029] A coordinate system that conforms to an underlying biaxial or tri-axial grid structure
may be defined, as will be described below in detail, using diffusion information,
such as diffusion vector information, obtained from diffusion weighted MR images.
The diffusion information can be analyzed to determine the principal direction of
white matter fiber paths in the brain. For those fiber paths extending predominantly
in the anterior-posterior ("AP") direction, the fiber paths are identified as extending
in the "longitudinal" direction of the defined coordinate system; for those fiber
paths extending predominantly in the left-right ("LR") direction, the fiber paths
are identified as extending in the "transverse" direction of the defined coordinate
system; and for those fiber paths extending predominantly in the superior-inferior
("SI") direction, the fiber paths are identified as extending in the "dorsoventral"
direction in the defined coordinate system.
[0030] Referring to FIG. 3, and by way of example, an exemplary fiber path for a superior
longitudinal fasciculus I ("SLF I") 302 as it crosses the corpus callosum 304 in a
volume-of-interest 306 is illustrated. The SLF I 302 predominantly extends in the
AP direction and the corpus callosum 304 extends predominantly in the LR direction
while curving about the AP axis, generally, in the SI direction. In accordance with
the present invention, a grid structure coordinate system for the SLF I 302 and corpus
callosum 304 fiber path neighborhoods may be advantageously defined by analyzing these
fiber paths. Because the SLF I 302 fiber path extends predominantly in the AP direction,
the SLF I 302 fiber path is assigned as extending along the longitudinal direction
in the grid structure coordinate system. Similarly, while the corpus callosum 304
curves in the SI direction, the predominant extension of the corpus callosum 304 fiber
path is in the LR direction; thus, the corpus callosum 304 fiber path is assigned
as extending along the transverse direction in the grid structure coordinate system.
[0031] In accordance with the present invention, the fiber paths can be mapped into and
transformed to and from the grid structure coordinate system. This bidirectional transform
is illustrated using the representative transfer function, f(), and inverse transfer
function, g(). The transfer function and inverse transfer functions will be described
below.
[0032] By way of the transfer function, f(), the SLF I 302 fiber paths and corpus callosum
304 fiber paths are illustrated as having been mapped into the grid structure coordinate
system. Thus, using the grid structure coordinate system of the present invention,
the fiber paths incident on the volume-of-interest 306 include two substantially orthogonal
components: longitudinal paths within the SLF I and transverse paths within the corpus
callosum.
[0033] Preliminarily, several observations regarding the grid structure coordinate system
of the present invention are of note. First, the present invention recognizes that
the curved paths of each directional component are substantially parallel. That is,
the component pathways are similar in orientation, generally, do not interweave with
each other, and their relative orderings remain. Second, the present invention recognizes
that pairs of transverse or longitudinal paths will not generally cross more than
once. Third, the present invention recognizes that fiber pathways are substantially
aligned with the cardinal body axes near the mid-sagittal plane, and that they continuously
curve away from these axes with distance while maintaining their orthogonal inter-relationships.
Thus, though curved, the grid structure in accordance with the present invention appears
simple, strict, and continuously related to the transverse and longitudinal axes of
the central nervous system and of the body. Thus, the present invention recognizes
that even though cerebral pathways may deviate from a single grid path, in doing so
the pathways still closely adhere to another grid orientation. The biaxial structure
of path neighborhoods is not limited to particular two-dimensional surfaces, but is
present throughout three-dimensional volumes. The pathways within each sheet in a
stack of sheets are parallel to their counterpart paths in sheets of different depths
in the stack.
[0034] Pathways of two different crossing families lie within the same extended, curved
two-dimensional surface. By the existence theorem for partial differential equations,
the likelihood of this phenomenon is expected to be significantly low. The discovery
that in the cerebral white matter, the mutual intersections of families of transverse
paths in three dimensions generally define a family of parallel sheets is therefore
real and non-trivial. Crossed direction fields in three dimensions, such as smooth
plane fields, do not generally specify well-defined curved two-dimensional surfaces,
but do so when they satisfy an auxiliary condition, such as that their mutual twist
is everywhere zero. This condition is specified, for example, by the Deahna-Clebsch-Frobenius
theorem. The mutual intersections of fiber paths through multiple seed volumes form
closed rectangles, and not open three-dimensional rectangular spirals that are overwhelmingly
expected for generic orientation fields.
[0035] As some exemplary illustrations detail below, these concepts can be extended into
a variety of useful extrapolations and extend or enhance a wide variety of clinical
applications. For example, still referring to FIG. 3, knowing that the curved paths
of each directional component are substantially parallel, that pairs of transverse
or longitudinal paths will not generally cross more than once, and that fiber pathways
are substantially aligned with the cardinal body axes near the mid-sagittal plane,
a variety of predictions and/or constraints on predictions or analysis can be made.
For example, in either domain, one can use the identification of the SLF I 302 fiber
paths and corpus callosum 304 fiber paths and a basis to predict and/or constrain
the prediction or identification of additional fiber paths 308. Specifically, using
the identification of the SLF I 302 fiber paths and corpus callosum 304 fiber paths
and/or the transform of these fiber paths 302, 304 onto the grid structure, one can
predict and/or constrain the prediction or identification of additional fiber paths
308 to be substantially parallel (in the case of the corpus callosum 304) or perpendicular
(in the case of the SLF I 302) and extend substantially aligned with the cardinal
body axes. As will be illustrated below, this ability to predict and/or constrain
prediction or analysis provides a highlypowerful tool for analyzing the human brain
in a myriad of clinical applications.
General Illustrations
[0036] Referring now to Fig. 4, in a basic application, one may identify fiber paths in
the brain, such as those described above with respect to FIG. 3, using vectors, generally
designated 400. More particularly, these vectors 400, when correlated in the image
domain, such as when beginning a fiber tractograpy application, may represent portions
of fiber tracts. In the illustration, these vectors 400 appear to be independent and
not interrelated. However, using the principles described above to constrain an analysis
of these vectors 400, it can be assumed that the curved paths of each directional
component are substantially parallel, that pairs of transverse or longitudinal component
will not generally cross more than once, and that vectors are substantially aligned
with the cardinal body. With these constraints, the vectors 400 can be analyzed and
designated, for example, using a marker that identifies the vector as extending along
a given component of the above-described, grid coordinate system. Specifically, the
vectors 400 can be assigned designations, in the illustrated example, numbers, that
identifies the vector as extending along a given component of the above-described,
grid coordinate system. Vectors extending along longitudinal direction are assigned
a "1" marker 402, those extending in the transverse direction are assigned a "2" marker
404, and those extending in the dorsoventral direction are assigned a "3" marker 406.
[0037] As will be described, this ability to constrain or resolve a preliminary assignment
of the vectors representing potential fiber tracts provides a powerful tool for enhancing
many traditional brain analyses and providing new mechanisms for analyzing the brain.
For example, as will be described in further detail, one can perform multi-dimensional,
interrelated tractography. Specifically, using the diffusion data acquired from a
subject, a first vector 402, and a second vector 404, the relative components of the
first vector 402 and the second vector 404 to one another can be evaluated to determine
a likelihood of correspondence to white matter fiber paths. For example, starting
with the first vector 402, further tractography can be performed to determine an extension
408 from the first vector potentially corresponding to additional portions of a white
matter fiber path. Comparing the relative components of the extension 408 from the
first vector to the other vectors 402, 404, 406, one can evaluate a likelihood of
correspondence to a white matter fiber path. Specifically, it can be determined that
the extension 408 of the first vector 402 yielded through tractographic processes
extends generally perpendicular to the first vector 402 and third vector 406 and parallel
to the second vector 404. By considering the relative components of the extension
408 from the first vector to the other vectors 402, 404, 406, one can determine that
the extension 408 has a relatively high likelihood of correspondence to a white matter
fiber path because it is substantially parallel or perpendicular to the vectors 402,
404, 406. That is, it can readily be assigned a assigned a "2" marker. On the other
hand, a extension 410 of the second vector 404, when compared to the other vectors
402, 404, 406, deviates from the expected parallel/perpendicular/substantially orthogonal
orientation and, thus, cannot be readily assigned any of the aforementioned markers.
However, it can also serve as important information. For example, it may indicate
that the extension 410, which may be derived through a traditional imaging and tractography
process, such as DTI, may not correctly correspond with an actual fiber path. For
example, the traditional imaging and tractography process, such as DTI, may have erroneously
resolved a fiber crossing. Accordingly, as will be described, the extension 410 may
be disregarded as part of an interrelated tractography process in favor of a more
properly resolved vector extension when compared to the other vectors 402, 404, 406,
or as described hereafter, a grid structure coordinate system. Additionally, the deviation
of the extension from the expected/predicted path may indicate a deformity of the
fiber paths, which also has substantial clinical value.
[0038] Accordingly, this process of comparing the relative components of the extension 408
from the first vector to the other vectors 402, 404, 406 is referred to as interrelated
tractography because, unlike traditional tractograpy procedures, it considers the
relation of a given vector/extension to other vectors/extensions. Furthermore, it
may be referred to as multi-dimensional interrelated tractography because it considers
the relative components, including magnitude and direction, of other potential fiber
tracts.
Vector Field Method for Defining Grid Structure Coordinate System
[0039] The above-described vector/assignment analysis can be extended to build more sophisticated
analysis and modeling tools. Referring to FIG. 5, a given plurality of vectors extending
substantially parallel and perpendicular, for example, those extending along the longitudinal
direction and those extending along the transverse direction, can be used to form
a function describing a plane 500 and vectors 502 extending perpendicular therefrom.
[0040] As described above, this procedure includes classifying each potential pathway represented
as a vector as one of longitudinal, transverse, and dorsoventral, such as by assigning
numerical markers. One can then calculate scalar potentials representative of the
principal axes (longitudinal, transverse, and dorsoventral), including a longitudinal
scalar potential,
φ(
l), a transverse scalar potential,
φ(
t), and a dorsoventral scalar potential,
φ(
d). For example, a vector in a white matter fiber path calculated using tractography
may define a location along that fiber path as a vector, v, having the following form:

where
vx = v(x),
vy =
v(
y)
, and
vz = v(z) are the vector components of the diffusion vector field location, v, along
the x-direction, y-direction, and z-direction, respectively. These vector components
can be related to the desired scalar potentials as follows:

and

where c(x),
c(y), and c(z) are constants. The result of solving, or approximating, some equations are
to determine those locations where the scalar potentials
φ(/),
φ(
t), and
φ(
d) point along the directions of the vector field components
v(
y), v(x), and v(z), where the vector field, v, is defined. Interpolation may be used
between locations in the vector field, v, to calculate the scalar potentials at a
location between those where the vector field, v, is defined.
[0041] Referring now to FIG. 6, a flowchart setting forth the steps of an exemplary method
for producing a coordinate system pertaining to a subject's neuroanatomy, such as
white matter tissue, is illustrated. The method begins with the acquisition of image
data from a subject using an MRI system, as indicated at step 602. As described above,
image data is acquired with a diffusion imaging scheme, such as DSI, Q-Ball imaging,
DTI, or other such techniques, using a pulse sequence such as, for example, the one
illustrated in FIG. 2. From the acquired image data, images of the subject are reconstructed,
as indicated at step 604. Because these images were produced using a diffusion imaging
scheme, they are indicative of diffusion occurring within tissues in the subject.
For example, images of the brain are indicative of diffusion occurring within brain
tissues, such as gray matter and white matter tissue. Using the reconstructed images,
a grid structure coordinate system may be defined, as indicated at step 606. Exemplary
methods for defining the grid structure coordinate system are described below in detail.
Following the generation of the grid structure coordinate system, the reconstructed
images of the subject and the grid structure coordinate system may be provided to
a user, as indicated at step 608, so that they can be used for subsequent applications.
[0042] Referring to FIGS. 7A, 7B, and 8, the above-described concepts can be utilized to
form a method for producing, or defining, a grid structure coordinate system 700 using
diffusion information contained in a vector field that describes diffusion occurring
in tissue pathways, such as white matter tissue fiber paths 702, as shown in FIG.
7A. More generally, as shown in FIG. 7B, a grid structure coordinate system 700 may
be mapped onto brain anatomy 704 in general, and vice versa. For illustrative purposes,
a portion 706 of the grid structure coordinate system 700 is shown overlaid with the
brain anatomy 704 to show aspects of the transformation that occurs when mapping between
the grid structure coordinate system 700 and the brain anatomy 704. An exemplary method
for defining a grid structure coordinate system using vector field information begins
by first providing diffusion vector field information, as indicated at step 802. This
diffusion information may be provided by performing tractography on the reconstructed
images that depict diffusion in the subject, and such tractography may be performed,
for example, using path integration or streamline tractography techniques. Alternatively,
however, diffusion information can be obtained from the reconstructed images. For
example, vector field information pertaining to diffusion can be obtained from diffusion
tensors or orientation distribution functions ("ODFs") calculated from the reconstructed
images.
[0043] The provided diffusion information is processed to define the grid structure coordinate
system. One or more points in the provided diffusion information are selected, as
indicated at step 804, and the vector field information at the one or more points
is utilized to perform multi-dimensional, interrelated tractography. Specifically,
as described above, using the diffusion data, a first vector, and a second vector,
the relative components of the first vector and the second vector to one another are
evaluated to determine a likelihood of correspondence to white matter fiber paths.
In one implementation, this may be extended by calculating scalar potentials that
define the grid structure coordinate system, as indicated at step 806. For example,
some equations may be solved using approximation methods to calculate the scalar potentials.
By constraining the scalar potentials to be nonzero along one principal direction
(e.g., longitudinal direction for the
φ(/) scalar potential) and substantially zero along the directions orthogonal to the
principal direction (e.g., transverse and dorsoventral directions for the
φ(
l) scalar potential), the grid structure coordinate system can be defined with respect
to the calculated scalar potentials, as indicated at step 808.
[0044] When fiber paths have already been calculated by tractography, the fiber paths may
be assigned to one of a longitudinal, transverse, and dorsoventral direction, in a
manner such as described above with respect to FIG. 4, for example, using the scalar
potential fields calculated at point associated with that fiber path. In addition,
orientation information, that is, whether the fiber path extends along the positive
or negative longitudinal, transverse, or dorsoventral direction, is preserved and
also be assigned to the fiber path.
Topology Method for Defining Grid Structure Coordinate System
[0045] Referring now to FIG. 9, a flowchart setting forth the steps of an exemplary method
for producing, or defining, a grid structure coordinate system using topological properties
of tissue pathways, such as white matter tissue fiber paths, is illustrated. Generally,
this procedure includes classifying each pathway as one of longitudinal, transverse,
and dorsoventral. White matter fiber tracts, such as those determined or calculated
using tractography, are provided, as indicated at step 902. From these white matter
fiber tracts, one or more fiber paths are selected for processing, as indicated at
step 904. Using the selected paths, path neighborhoods are determined throughout the
subject's brain, or a portion thereof, as indicated at step 906. For any given path,
the set of all other paths that approach the given path to within a distance of, for
example, one voxel is computed. Such paths are referred to as being "adjacent," and
the set of all paths that are adjacent to a selected set of paths is referred to as
the "neighborhood" of those selected paths. This adjacency includes as special cases
both tangency and the crossing of paths. Adjacency represents a simple and neutral
probe of the relational structure of the set of pathways, being equivalent to the
definition of a topology on the space of paths. Thus, a topology of the fiber pathways
in the brain is defined on path space using this adjacency.
[0046] Having identified the fiber paths and determined the path neighborhoods within the
subject's brain, or the portion thereof, a coordinate system pertaining to the subject's
neuroanatomy is determined, as indicated generally at 908. To produce a grid structure
coordinate system, the paths adjacent a selected path are first classified as one
of functionally parallel; part of the same fiber system; or functionally crossing,
intersecting, or perpendicular, as indicated at step 910. Two remote paths are determined
to be functionally parallel when intermediate paths spaced between the two remote
paths are parallel to the remote paths. Thus, a transitive property of functionally
parallel pathways is used. When two paths are not functionally parallel, they are
determined to be functionally perpendicular. As noted above, the fiber paths are identified
as belonging to one of a transverse, longitudinal, or dorsoventral principal coordinate
direction. Fiber coordinates and fiber grid relations are used to identify this directionality
of the fiber paths, as indicated at step 912. Fibers adjacent to a selected fiber
may be decomposed into tangent (parallel) and crossing (perpendicular) fiber groups.
Such a process can be advantageously utilized in particular clinical applications,
some of which are described below, or more generally as described above.
Method for Producing Fiber Sheet Conformal Coordinates
[0047] Referring now to FIG. 10, a flowchart setting forth the steps of an exemplary method
for producing fiber sheet conformal coordinates, such as referred to with respect
to FIG. 5, is illustrated. A sheet of fibers may be produced from a set of fibers
crossing a selected fiber. Likewise, a sheet of fibers may be produced from a set
of fibers that mutually cross two selected fibers. Generally, fiber sheet conformal
coordinates can be produced, given two sets of crossing paths, by defining a coordinate
{x,y}, where x is a path distance measured alone one set of paths and y is a distance
measured along the other. Thus, the method begins by selecting sets of fiber paths,
as indicated at step 1002. The path lengths x and y are then measured along the selected
sets of fiber paths, as indicated at step 1004, to define a local conformal coordinate.
This local coordinate may then be smoothed and locally extended to three dimensions,
as indicated at steps 1006 and 1008, respectively. Parallel fiber sheets can then
be produced using the procedure described above, but extended to three dimensions.
For example, the coordinates between parallel fibers and parallel sheets can be extended.
Fiber volume conformal coordinates can then be produced as described above for sheet
conformal coordinates, but expanded to three dimensions. For example, given overlapping
fiber systems, the coordinates can be extended to cover their union. Fiber coordinates
for the entire brain can be created in this manner by overlapping systems. These coordinates
may be standardized in relation to standard anatomical landmarks, such as the brain
mid-line, AC-PC line, or other observables such as the center of mass or moment of
inertia of the brain. Such a process can be advantageously utilized in particular
clinical applications, some of which are described below, or more generally as described
above.
[0048] Having described methods for producing a grid structure coordinate system for white
matter fiber pathways, several exemplary applications of such a coordinate system
are now provided.
Comparison of Two or More Images
[0049] Referring now to FIG. 11A, a flowchart setting forth the steps of an exemplary method
for comparing medical images of two or more subjects using a grid structure coordinate
system is illustrated. That is, as explained above, the predictive nature of the present
invention provides a mechanism through which sub-components of tractography, such
as vectors or proposed extensions from vectors, can be evaluated with respect to one
another. However, the evaluative uses of the present invention can likewise extend
across multiple tractographic images. The method begins by providing medical images
of the subjects and respective grid structure coordinate system information, as indicated
at step 1102. Exemplary medical images that may be provided include magnetic resonance
images such as T1-weighted, T2-weighted, diffusion weighted, functional, and contrast-enhanced
or non-contrast-enhanced MR angiography images. Other exemplary medical images may
include those acquired with x-ray imaging systems, including x-ray computed tomography
("CT") systems, and nuclear medicine imaging systems, including positron emission
tomography ("PET") and single photon emission computed tomography ("SPECT") systems.
Using the provided medical images and grid structure coordinate system information,
each medical image can be mapped into the grid structure coordinate system, as indicated
at step 1104, so that accurate and reliable comparisons can be made between the mapped
medical images, as indicated at step 1106. Such comparisons may produce comparative
information that serve as a metric indicative of characteristics of the subjects under
examination.
[0050] By way of example, medical images, such as magnetic resonance images, of two or more
brains from different subjects or multiple images of the same subject may be compared
using known comparison and statistical methods after they have been mapped into the
grid structure coordinate system. Using the example of comparing two brains from different
subjects, because the brains share a common coordinate system that conforms to the
subject's anatomy on one level, but describes a generalized anatomical relationship
on another level, such comparisons can be made more reliably by mapping the relevant
information to be compared into their respective coordinate systems before comparison.
Average Image
[0051] Referring now to FIG. 11B, a flowchart setting forth the steps of an exemplary method
for producing an average image from medical images obtained for multiple different
subjects, and using a grid structure coordinate system, is illustrated. The method
begins by providing medical images of the subjects and respective grid structure coordinate
system information, as indicated at step 1108. Exemplary medical images that may be
provided include magnetic resonance images such as T1-weighted, T2-weighted, diffusion
weighted, functional, and contrast-enhanced or non-contrast-enhanced MR angiography
images. Other exemplary medical images may include those acquired with x-ray imaging
systems, including x-ray CT systems, and nuclear medicine imaging systems, including
PET and SPECT systems.
[0052] Using the provided medical images and grid structure coordinate system information,
each medical image can be mapped into the grid structure coordinate system, as indicated
at step 1110. An "average" medical image can be created by averaging together the
mapped medical images, as indicated at step 1112. Such an average image may be useful
as a universal anatomical atlas that is based on the grid structure coordinate system,
or for calculating normative data. For example, as indicated at step 1114, normative
data for observables, such as average T1 or T2 values for particular tissue types,
can be computed. Deviations from these normative data can then be measured on an individual
basis and used as an informative diagnostic biomarker. In this manner, such normative
data serves as a metric representative of a characteristic of a subject.
Connectivity
[0053] Referring now to FIG. 11C, a flowchart setting forth the steps of an exemplary method
for measuring and producing an image representative of the connectivity of fiber pathways
in a subject's brain using a grid structure coordinate system is illustrated. The
method begins by providing medical images of the subjects and respective grid structure
coordinate system information, as indicated at step 1116. Exemplary medical images
that may be provided include magnetic resonance images such as T1-weighted,T2-weighted,
diffusion weighted, functional, and contrast-enhanced or non-contrast-enhanced MR
angiography images. Other exemplary medical images may include those acquired with
x-ray imaging systems, including x-ray CT systems, and nuclear medicine imaging systems,
including PET and SPECT systems. Using the provided medical images and grid structure
coordinate system information, each medical image can be mapped into the grid structure
coordinate system, as indicated at step 1118
[0054] Connectivity of the brain can be described and measured using the produced grid structure
coordinate system. For example, general connectivity can be measured between two or
more longitudinal, transverse, and dorsoventral, or {l,t,d}, coordinates, and cortical
connectivity may be measured between two longitudinal, transverse, or {l,t}, coordinates,
as indicated at step 1120. This latter example may include the projection from three-dimensional
{l,t,d} coordinates to two-dimensional {l,t} coordinates. Fiber path connectivity
may also be measured by projecting each component onto itself. For example, longitudinal
connectivity may be measured by producing a three-dimensional image that may specify
at each point, for example, the projected longitudinal component, l', or the spatial
path offset (path length), l-l'. The entire connectome may then be represented by
three such images, one for each principal {l,t,d} coordinate; thus, images representative
of such fiber connectivity may be produced, as indicated at step 1122. Such images
represent a metric that is indicative of a characteristic of the subject; for example,
such a metric may represent the connectivity of fibers in the subject's brain.
Fiber Density Metric
[0055] Referring now to FIG. 11D, a flowchart setting forth the steps of an exemplary method
for calculating a fiber density measure using a grid structure coordinate system is
illustrated. The method begins by providing medical images of the subjects and respective
grid structure coordinate system information, as indicated at step 1124. Exemplary
medical images that may be provided include magnetic resonance images such as T1-weighted,T2-weighted,
diffusion weighted, functional, and contrast-enhanced or non-contrast-enhanced MR
angiography images. Other exemplary medical images may include those acquired with
x-ray imaging systems, including x-ray CT systems, and nuclear medicine imaging systems,
including PET and SPECT systems. The provided grid structure coordinate system is
then scaled, or rescaled, as indicated at step 1126. For example, the coordinates
can be scaled or rescaled to be representative of the total number of pathways over
a particular distance in the grid structure coordinate system. Using the provided
medical images and scaled grid structure coordinate system information, each medical
image can be mapped into the grid structure coordinate system, as indicated at step
1128. The density of fibers in the subject can then be measured and normalized using
the scaled grid structure coordinate system and mapped medical images, as indicated
at step 1130. In this manner, a metric in the form of a normalized measure of fiber
density can be provided across different subjects.
Coordinate System Accuracy
[0056] Referring now to FIG. 11E, a flowchart setting forth the steps of an exemplary method
for measuring the accuracy of a grid structure coordinate system is illustrated. The
method begins by providing medical images of the subjects and respective grid structure
coordinate system information, as indicated at step 1132. Exemplary medical images
that may be provided include magnetic resonance images such as T1-weighted,T2-weighted,
diffusion weighted, functional, and contrast-enhanced or non-contrast-enhanced MR
angiography images. Other exemplary medical images may include those acquired with
x-ray imaging systems, including x-ray CT systems, and nuclear medicine imaging systems,
including PET and SPECT systems. Using the provided medical images and grid structure
coordinate system information, each medical image can be mapped into the grid structure
coordinate system, as indicated at step 1134.
[0057] The accuracy of the coordinate system itself can be assessed by, for example, computing
a measure of the coordinate system, such as a so-called "Frobenius defect," or closure
defect of the coordinates. In such a method, a starting point in a fiber pathway in
the coordinate system is selected, as indicated at step 1136. From this starting point,
a sequence of fiber segments is produced, as indicated at step 1138. These fiber segments
are produced such that in a Cartesian coordinate system, they would form a closed
polygon or curve. A vector across the final closure gap of this sequence of fiber
segments is then measured, as indicated at step 1140. By way of example, consider
four steps along coordinate directions "a" and "b":

[0058] The vector representation of the gap from the start to the finish in this example
is given by:

[0059] These gap closure defects show the "singularities" in the paths of the brain. For
any two coordinate directions, these closure defects can be computed at every point
where both directions are defined. Thus, an "image" of the closure defects can be
produced and displayed, as indicated at step 1142. Because this closure gap image
represents a measure of a grid structure coordinate system that pertains to a particular
subject, such closure gap measures are metrics indicative of a characteristic of a
subject, such as the grid structure coordinate system defined with respect to the
subject.
Method for Regression Analysis
[0060] Referring now to FIG. 11F, a flowchart setting forth the steps of an exemplary method
for producing an image of a subject's anatomy, such as the subject's brain, at a different
age of the subject using a grid structure coordinate system is illustrated. The method
begins by providing medical images of the subjects and respective grid structure coordinate
system information, as indicated at step 1144. Exemplary medical images that may be
provided include magnetic resonance images such as T1-weighted,T2-weighted, diffusion
weighted, functional, and contrast-enhanced or non-contrast-enhanced MR angiography
images. Other exemplary medical images may include those acquired with x-ray imaging
systems, including x-ray CT systems, and nuclear medicine imaging systems, including
PET and SPECT systems. Using the provided medical images and grid structure coordinate
system information, each medical image can be mapped into the grid structure coordinate
system, as indicated at step 1146. These mapped images can then be regressed to a
different age of the subject using a model of tissue organization for the subject,
as indicated at step 1148. In this manner, images of the subject's anatomy at different
ages of the subject can be produced, thereby providing a metric of the subject's anatomical
growth.
[0061] Thus, the present invention recognizes and defines herein a "grid structure" of cerebral
white matter that indicates the presence of previouslyunrecognized constraints on
the geometry and topology of cerebral connectivity, with implications for the evolution,
development, plasticity, and function of the brain. Relative to previous models of
cerebral connectivity that allowed relatively independent connectivity among any set
of cortical areas, the grid structure of the present invention implies a marked reduction
in the dimensionality of the space of cerebral fiber pathways. Developmentally, the
grid structure of the present invention makes the problems of axonal navigation and
path-finding simpler and more restricted than would independent regional connectivity.
The grid structure of the present invention also provides a framework within which
more complex connectivity may arise from simpler structure through incremental differential
growth. Thus, the grid structure of the present invention, and the underlying coordinate
system of the present invention that is representative of this grid structure, can
be used to provide a natural substrate for gradual adaptation of connectivity, critical
to plasticity and evolution.
[0062] It is contemplated that, functionally, the parallel pathways of the grid structure
of the present invention helps preserve the spatial order and temporal coherence of
signals over larger scales than would discrete fiber bundles. Thus, this grid structure
may constitute a favorable substrate for neural coding utilizing topographic coherence
and temporal synchrony. Spatiotemporal coherence can lead naturally to cortico-cortical
mappings that preserve the local shapes of activation patterns. Thus, such cortico-cortical
mappings are angle-preserving, or conformal, mappings between two-dimensional cortical
areas. It is contemplated that the nearorthogonal three-dimensional structure of the
fiber pathways would be a natural counterpart to two-dimensional conformal structure
of cortical connectivity.
[0063] The implications of the grid structure of the present invention for brain mapping
are several. First, it is contemplated that grid structure simplifies the description
and quantification of the cerebral connectome by greatly reducing the dimensionality
of its space of possible variation. This facilitates comparisons across groups and
species, and between individuals. Second, a basic problem for diffusion MRI is the
question of validation given the absence of effective gold-standards in humans. In
this context, the grid structure of the present invention, and the underlying coordinate
system representative of the grid structure, may contribute to validation of diffusion
MRI of cerebral connectivity based on geometric self-consistency, such as the existence
of geometrically well-defined sheets. Third, constraints represented by the grid structure
of the present invention can improve biophysical models of cerebral diffusion and
aid in the discovery and measurement of effective biomarkers for connectional diseases,
such as multiple sclerosis. Fourth, as described above, the grid structure of the
present invention is useful in the construction of natural coordinate systems for
the brain.
1. Verfahren zum Erzeugen eines Bildes eines Subjekts, wobei die Schritte des Verfahrens
umfassen:
a) Erfassen von Bilddaten (602) eines Gehirns des Subjekts, das Gewebe von weißer
Substanz umfasst, das Fasern der weißen Substanz umfasst, wobei die Bilddaten Diffusionsinformationen
umfassen;
b) Rekonstruieren (604) eines Bildes des Subjekts aus den Bilddaten, das die Fasern
der weißen Substanz darstellt;
c) Erzeugen von Koordinatensysteminformationen (606) durch Korrelieren der Fasern
der weißen Substanz in dem rekonstruierten Bild mit einem Koordinatensystem, das so
definiert ist, dass die Fasern der weißen Substanz in einem im Wesentlichen orthogonalen
Gitter angeordnet sind, und wobei Faserpfade in den Fasern der weißen Substanz entlang
Achsen angeordnet sind, die das im Wesentliche orthogonale Gitter definieren; und
d) Bereitstellen (608) des rekonstruierten Bildes und der erzeugten Koordinatensysteminformationen
für einen Benutzer.
2. Verfahren nach Anspruch 1, bei dem das erzeugte Koordinatensystem in Bezug auf einen
anatomischen Orientierungspunkt des Subjekts zentriert ist, der wenigstens eines von
einer Mittellinie des Gehirns und einer Commissura anterior-Commissura posterior-Linie
umfasst.
3. Verfahren nach Anspruch 1, bei dem in dem Gitter angeordnete Fasern der weißen Substanz
wenigstens eines umfasst von Abschnitten von Fasern der weißen Substanz, die mit anderen
Abschnitten von Fasern der weißen Substanz verwoben sind, und Abschnitten von Fasern
der weißen Substanz, die in Schichten von parallelen Faserpfaden der weißen Substanz
angeordnet sind.
4. Verfahren nach Anspruch 1, bei dem Schritt c) Auswählen eines Faserpfads der weißen
Substanz in den Fasern der weißen Substanz und Identifizieren anderer Faserpfade der
weißen Substanz neben dem ausgewählten Faserpfad der weißen Substanz umfasst.
5. Verfahren nach Anspruch 4, bei dem Schritt c) wenigstens eines umfasst von:
Durchführen von Traktographie an den in Schritt b) rekonstruierten Bildern, um Faserpfade
der weißen Substanz in den Fasern der weißen Substanz zu bestimmen; und
Identifizieren einer Nachbarschaft von Faserpfaden der weißen Substanz neben dem ausgewählten
Faserpfad der weißen Substanz.
6. Verfahren nach Anspruch 4, bei dem Schritt c) Zuordnen des ausgewählten Faserpfads
der weißen Substanz und der identifizierten anderen Faserpfade der weißen Substanz
einer Hauptrichtung umfasst, die im Wesentlichen mit Hauptachsen des Subjekts ausgerichtet
ist und die wenigstens einer entspricht von longitudinal, transversal und dorsoventral.
7. Verfahren nach Anspruch 1, wobei die in Schritt d) erzeugten Koordinatensysteminformationen
eine Metrik sind, die auf eine Eigenschaft des Subjekts hinweist.
8. Verfahren nach Anspruch 7, bei dem Schritt d) Gewichten des rekonstruierten Bildes
unter Verwendung des definierten Koordinatensystems umfasst.
9. Verfahren nach Anspruch 8, bei dem die in Schritt d) erzeugte Metrik eine Messung
der Faserkonnektivität der weißen Substanz ist, und bei dem Schritt d) Bestimmen eines
Konnektivitätsmaßes zwischen zwei oder mehr Punkten in dem rekonstruierten Bild unter
Verwendung des definierten Koordinatensystems umfasst.
10. Verfahren nach Anspruch 8, bei dem die in Schritt d) erzeugte Metrik wenigstens eines
umfasst von:
Eigenschaften von Fasern der weißen Substanz in dem Subjekt bei unterschiedlichem
Alter des Subjekts, und wobei Schritt d) Durchführen einer Regression an dem Bild
des Subjekts unter Verwendung des definierten Koordinatensystems umfasst, das auf
Fasern der weißen Substanz hinweist,
eine Messung einer Genauigkeit des definierten Koordinatensystems;
eine Lückenschließung im definierten Koordinatensystem.
11. Verfahren nach Anspruch 1, ferner umfassend Bestimmen von Faserpfaden der weißen Substanz,
umfassend die Schritte:
Bestimmen eines ersten Vektors aus den Diffusionsinformationen, der potentiell einem
Abschnitt eines ersten Faserpfads der weißen Substanz entspricht;
Bestimmen eines zweiten Vektors aus den Diffusionsinformationen, der potentiell einem
Abschnitt eines zweiten Faserpfads der weißen Substanz entspricht, und ferner umfassend
die Schritte:
Durchführen eines zusammenhängenden Traktographieverfahrens unter Verwendung der Diffusionsinformationen,
des ersten Vektors und des zweiten Vektors und Berücksichtigen relativer Komponenten
des ersten Vektors und des zweiten Vektors zueinander, um eine Übereinstimmungswahrscheinlichkeit
mit dem ersten Faserpfad der weißen Substanz und dem zweiten Faserpfad der weißen
Substanz zu bewerten; und
Aufbauen einer Darstellung des ersten Faserpfads der weißen Substanz und des zweiten
Faserpfads der weißen Substanz.
12. Verfahren nach Anspruch 11, wobei das Durchführen des zusammenhängenden Traktographieverfahrens
ferner Bestimmen von Verlängerungen von dem ersten Vektor und dem zweiten Vektor umfasst,
die potentiell jeweils zusätzlichen Abschnitten des ersten Faserpfads der weißen Substanz
und des zweiten Faserpfads der weißen Substanz entsprechen, und Berücksichtigen relativer
Komponenten der Verlängerungen von dem ersten Vektor und dem zweiten Vektor zueinander,
um eine Übereinstimmungswahrscheinlichkeit mit dem ersten Faserpfad der weißen Substanz
und dem zweiten Faserpfad der weißen Substanz zu bewerten.
13. Verfahren nach Anspruch 11, wobei Schritt c) ferner Erzeugen von Koordinatensysteminformationen
durch Korrelieren des ersten Vektors und des zweiten Vektors mit dem Koordinatensystem
umfasst.
14. Verfahren nach Anspruch 11, wobei das Bestimmen von weißer Substanz
Bestimmen eines dritten Vektors aus den Diffusionsinformationen umfasst, der potentiell
einem Abschnitt eines dritten Faserpfads der weißen Substanz entspricht;
Zuordnen einer Hauptrichtung des ersten Vektors, des zweiten Vektors, und des dritten
Vektors, die einem entspricht von longitudinalen, transversalen und dorsoventralen
Orientierungen in dem Gehirn des Subjekts; und
Aufbauen einer Darstellung des ersten Faserpfads der weißen Substanz, des zweiten
Faserpfads der weißen Substanz und des dritten Faserpfads der weißen Substanz unter
Berücksichtigung von Vektormarkierungseinschränkungen und relativen Komponenten des
ersten Vektors, des zweiten Vektors und des dritten Vektors und der zugeordneten Hauptrichtung
zueinander.
15. Nichtflüchtiges computerlesbares Speichermedium mit darauf gespeicherten Anweisungen,
die, wenn sie von einem Prozessor ausgeführt werden, den Prozessor anweisen, ein Verfahren
zum Erzeugen eines Bildes eines Subjekts durchzuführen, wobei die Schritte des Verfahrens
umfassen:
a) Empfangen von Bilddaten (602) eines Gehirns des Subjekts, das Gewebe von weißer
Substanz umfasst, wobei die Bilddaten Diffusionsinformationen über das Gewebe der
weißen Substanz widerspiegeln, das Fasern der weißen Substanz umfasst;
b) Rekonstruieren (604) eines Bildes des Subjekts aus den Bilddaten, welches das Fasergewebe
der weißen Substanz darstellt;
c) Erzeugen von Koordinatensysteminformationen (606) durch Korrelieren der Fasern
der weißen Substanz in dem rekonstruierten Bild mit einem Koordinatensystem, das so
definiert ist, dass die Fasern der weißen Substanz in einem im Wesentlichen orthogonalen
Gitter angeordnet sind, und wobei Faserpfade in den Fasern der weißen Substanz entlang
Achsen angeordnet sind, die das im Wesentlichen orthogonale Gitter definieren; und
d) Bereitstellen (608) des rekonstruierten Bildes und der erzeugten Koordinatensysteminformationen
für einen Benutzer über eine Anzeige.
1. Procédé de production d'une image d'un sujet, les étapes du procédé comprenant de
:
a) acquérir des données d'image (602) du cerveau du sujet qui comprend du tissu de
substance blanche, contenant des fibres de substance blanche, dans lequel les données
d'image incluent des informations de diffusion ;
b) reconstruire (604) à partir des données d'image, une image du sujet qui représente
les fibres de substance blanche ;
c) produire des informations de système de coordonnées (606) en corrélant les fibres
de substance blanche sur l'image reconstruite avec un système de coordonnées défini
de telle sorte que les fibres de substance blanche soient disposées dans une grille
sensiblement orthogonale, et dans lequel des voies de fibres dans les fibres de substance
blanche sont disposées le long d'axes définissant la grille sensiblement orthogonale
; et
d) fournir (608) l'image reconstruite et les informations de système de coordonnées
produites à un utilisateur.
2. Procédé selon la revendication 1, dans lequel le système de coordonnées produit est
centré par rapport à un repère anatomique du sujet comprenant une ligne médiane du
cerveau et/ou une ligne de commissure antéropostérieure.
3. Procédé selon la revendication 1, dans lequel les fibres de substance blanche disposées
dans la grille comprennent des parties de fibres de substance blanche qui sont entrelacées
avec d'autres parties de fibres de substance blanche et/ou des parties de fibres de
substance blanche disposées en nappes de voies parallèles de fibres de substance blanche.
4. Procédé selon la revendication 1, dans lequel l'étape c) inclut la sélection d'une
voie de fibre de substance blanche dans les fibres de substance blanche et l'identification
d'autres voies de fibres de substance blanche adjacentes à la voie de fibre de substance
blanche sélectionnée.
5. Procédé selon la revendication 4, dans lequel l'étape c) inclut au moins l'une des
étapes suivantes :
réaliser une tractographie sur les images reconstruites à l'étape b) pour déterminer
des voies de fibres de substance blanche dans les fibres de substance blanche ; et
identifier un voisinage de voies de fibres de substance blanche adjacentes à la voie
de fibre de substance blanche sélectionnée.
6. Procédé selon la revendication 4, dans lequel l'étape c) inclut l'attribution à la
voie de fibre de substance blanche sélectionnée et aux autres voies de fibres de substance
blanche identifiées une direction principale qui est sensiblement alignée avec des
axes cardinaux du sujet et qui est longitudinale et/ou transversale et/ou dorsoventrale.
7. Procédé selon la revendication 1, dans lequel les informations de système de coordonnées
produites à l'étape d) consistent en un paramètre de mesure indiquant une caractéristique
du sujet.
8. Procédé selon la revendication 7, dans lequel l'étape d) inclut la pondération de
l'image reconstruite à l'aide du système de coordonnées défini.
9. Procédé selon la revendication 8, dans lequel le paramètre de mesure produit à l'étape
d) est une mesure de la connectivité des fibres de substance blanche, et dans lequel
l'étape d) inclut la détermination d'une mesure de connectivité entre deux points
ou plus sur l'image reconstruite à l'aide du système de coordonnées défini.
10. Procédé selon la revendication 8, dans lequel le paramètre de mesure produit à l'étape
d) comprend :
des caractéristiques de fibres de substance blanche chez le sujet à un âge différent
du sujet, et l'étape d) inclut la réalisation d'une régression sur l'image du sujet
qui indique des fibres de substance blanche à l'aide du système de coordonnées défini,
et/ou
une mesure de la précision du système de coordonnées défini ; et/ou
un écart de fermeture dans le système de coordonnées défini.
11. Procédé selon la revendication 1, comprenant en outre la détermination de voies de
fibres de substance blanche, comprenant les étapes consistant à :
déterminer un premier vecteur à partir des informations de diffusion correspondant
potentiellement à une partie d'une première voie de fibre de substance blanche ;
déterminer un deuxième vecteur à partir des informations de diffusion correspondant
potentiellement à une partie d'une deuxième voie de fibre de substance blanche, et
comprenant en outre les étapes consistant à :
réaliser une procédure de tractographie interdépendante en utilisant les informations
de diffusion, le premier vecteur et le deuxième vecteur et en prenant en compte des
composantes relatives du premier vecteur et du deuxième vecteur les unes par rapport
aux autres pour évaluer une vraisemblance de correspondance avec la première voie
de fibre de substance blanche et la deuxième voie de fibre de substance blanche ;
et
construire une représentation de la première voie de fibre de substance blanche et
de la deuxième voie de fibre de substance blanche.
12. Procédé selon la revendication 11, dans lequel la réalisation de la procédure de tractographie
interdépendante comprend en outre la détermination de prolongements à partir du premier
vecteur et du deuxième vecteur correspondant potentiellement à des parties supplémentaires
de la première voie de fibre de substance blanche et de la deuxième voie de fibre
de substance blanche, respectivement, et la prise en compte de composantes relatives
des prolongements à partir du premier vecteur et du deuxième vecteur les unes par
rapport aux autres pour évaluer une vraisemblance de correspondance avec la première
voie de fibre de substance blanche et la deuxième voie de fibre de substance blanche.
13. Procédé selon la revendication 11, dans lequel l'étape c) inclut en outre la production
d'informations de système de coordonnées par corrélation du premier vecteur et du
deuxième vecteur avec le système de coordonnées.
14. Procédé selon la revendication 11, dans lequel la détermination de la substance blanche
comprend de :
déterminer un troisième vecteur à partir des informations de diffusion correspondant
potentiellement à une partie d'une troisième voie de fibre de substance blanche ;
attribuer une direction principale du premier vecteur, du deuxième vecteur et du troisième
vecteur correspondant à une orientation longitudinale ou transversale ou dorsoventrale
dans le cerveau du sujet ; et
construire une représentation de la première voie de fibre de substance blanche, de
la deuxième voie de fibre de substance blanche et de la troisième voie de fibre de
substance blanche en tenant compte de contraintes de marqueurs vectoriels et de composantes
relatives du premier vecteur, du deuxième vecteur et du troisième vecteur ainsi que
de la direction principale attribuée des uns par rapport aux autres.
15. Support de stockage non transitoire lisible par ordinateur, sur lequel sont stockées
des instructions qui, lorsqu'elles sont exécutées par un processeur, ordonnent au
processeur de mettre en œuvre un procédé pour produire une image d'un sujet, les étapes
du procédé comprenant de :
a) recevoir des données d'image (602) du cerveau du sujet qui comprend du tissu de
substance blanche, les données d'image reflétant des informations de diffusion concernant
le tissu de substance blanche, contenant des fibres de substance blanche ;
b) reconstruire (604) à partir des données d'image, une image du sujet qui représente
le tissu à fibres de substance blanche ;
c) produire des informations de système de coordonnées (606) en corrélant les fibres
de substance blanche sur l'image reconstruite avec un système de coordonnées défini
de telle sorte que les fibres de substance blanche soient disposées dans une grille
sensiblement orthogonale, et dans lequel des voies de fibres dans les fibres de substance
blanche sont disposées le long d'axes définissant la grille sensiblement orthogonale
; et
d) fournir (608) l'image reconstruite et les informations de système de coordonnées
produites à un utilisateur par l'intermédiaire d'un dispositif d'affichage.